JP2021111522A - Power storage module - Google Patents

Abstract

To provide a power storage module that can improve the manufacturing efficiency.SOLUTION: A power storage module 11 includes bipolar electrodes 16A and 16B, and a flexible printed board 50 including a conductive pattern 52 that transmits a signal about the voltage of an electrode body 21A and a conductive pattern 53 that transmits a signal about the voltage of an electrode body 21B. The flexible printed board 50 includes a connection part 56 held between a tab 21d of the electrode body 21A and a tab 21d of the electrode body 21B in a first direction. The conductive pattern 52 is electrically connected to the tab 21d of the electrode body 21A through an opening 56c provided to a surface 56a of the connection part 56. The conductive pattern 53 is electrically connected to the tab 21d of the electrode body 21B through an opening 56d provided to a surface 56b of the connection part 56.SELECTED DRAWING: Figure 4

Description

The present disclosure relates to a power storage module.

A configuration is known in which a flexible printed circuit board is used to measure the voltage of a bipolar battery. For example, in the bipolar secondary battery described in Patent Document 1, the current collector of the bipolar electrode has an extending portion extending outside the cell cell layer, and the conductive pattern of flexible wiring is provided in this extending portion. Are electrically connected.

Japanese Unexamined Patent Publication No. 2008-117626

In the bipolar secondary battery described in Patent Document 1, a connection lead portion including a flexible substrate and a conductive pattern formed on one surface of the flexible substrate and a cover material covering the conductive pattern is provided for each current collector. ing. Therefore, in the manufacturing process of such a power storage module, the number of man-hours for assembling the flexible printed circuit to connect to the current collector increases, and the manufacturing efficiency of the power storage module may decrease.

The present disclosure describes a power storage module capable of improving manufacturing efficiency.

The power storage module according to one aspect of the present disclosure includes a first electrode body and a first electrode body including two active material layers having different polarities provided on both sides of the first electrode body, a second electrode body, and a first electrode body. A second electrode including two active material layers having different polarities provided on both sides of the two electrode bodies, and a first conductive pattern for transmitting a signal regarding the voltage of the first electrode body and a signal regarding the voltage of the second electrode body. A flexible printed substrate including a second conductive pattern to be transmitted is provided. The first electrode and the second electrode are the first so that the first polar active material layer provided on the first electrode body and the second polar active material layer provided on the second electrode body face each other. Stacked along the direction. The first electrode body has a first main body portion provided with two active material layers of the first electrode, and a first tab extending from the first main body portion in a second direction intersecting the first direction. The second electrode body has a second main body portion provided with two active material layers of the second electrode, and a second tab extending in the second direction from the second main body portion. The flexible printed circuit board has a connection portion sandwiched between the first tab and the second tab in the first direction. The connecting portion has a first surface facing the first tab and a second surface facing the second tab. A first opening is provided on the first surface at a position overlapping the first tab when viewed from the first direction so that a part of the first conductive pattern is exposed. A second opening is provided on the second surface at a position overlapping the second tab when viewed from the first direction so that a part of the second conductive pattern is exposed. The first conductive pattern is electrically connected to the first tab via the first opening. The second conductive pattern is electrically connected to the second tab via the second opening.

In this power storage module, the connection portion of the flexible printed circuit is sandwiched between the first tab of the first electrode body of the first electrode and the second tab of the second electrode body of the second electrode, and is placed on the first surface of the connection portion. The first conductive pattern is electrically connected to the first tab through the first opening provided, and the second conductive pattern is connected to the second tab through the second opening provided on the second surface of the connecting portion. Is electrically connected to. That is, one flexible printed circuit board is provided for two electrode bodies. Therefore, the number of assembling man-hours for connecting the flexible printed circuit board to the electrode body can be reduced as compared with the case where one flexible printed circuit board is provided for each electrode body. As a result, it becomes possible to improve the manufacturing efficiency of the power storage module.

The second tab may be provided at a position different from that of the first tab in the first direction and the third direction intersecting the second direction. In this configuration, the distance between the first tab and the second tab is longer than in the case where the second tab is provided at the same position as the first tab in the third direction. Therefore, since the insulation distance between the first tab and the second tab can be secured, the possibility that the first electrode body and the second electrode body are short-circuited can be reduced.

The power storage module includes a third electrode body, a third electrode including two active material layers having different polarities provided on both sides of the third electrode body, and a support member for supporting the second tab. You may also prepare for it. The second electrode and the third electrode are the first so that the first polar active material layer provided on the second electrode body and the second polar active material layer provided on the third electrode body face each other. It may be laminated along the direction. The third electrode body may have a third main body portion provided with two active material layers of the third electrode, and a third tab extending in the second direction from the third main body portion. The support member may be arranged so as to be sandwiched between the second tab and the third tab in the first direction. In this configuration, the second tab is supported by the support member. Therefore, even if a force is applied to the second tab from the flexible printed circuit board, the bending of the second tab is suppressed, so that the possibility of the second tab breaking can be reduced.

The elastic modulus of the support member may be smaller than the elastic modulus of the flexible printed circuit board. For example, due to the dimensional tolerance of the flexible printed circuit, the length of the connection portion of the flexible printed circuit in the first direction may be larger than the distance between the first tab and the second tab in the first direction. be. According to the above configuration, the support member is compressed, so that the dimensional tolerance of the flexible printed circuit board can be absorbed.

The third tab may be provided at a position different from that of the second tab in the third direction intersecting the first direction and the second direction. The support member may be provided so as to overlap the second tab and the third tab when viewed from the first direction. In this configuration, the distance between the second tab and the third tab is longer than in the case where the third tab is provided at the same position as the second tab in the third direction. Therefore, since the insulation distance between the second tab and the third tab can be secured, the possibility that the second electrode body and the third electrode body are short-circuited can be reduced.

According to the present disclosure, manufacturing efficiency can be improved.

FIG. 1 is a schematic side view showing a power storage device according to an embodiment. FIG. 2 is a schematic plan view of the power storage module included in the power storage device of FIG. FIG. 3 is a schematic cross-sectional view taken along the line III-III of FIG. FIG. 4 is an enlarged view of a part of the cross section shown in FIG. FIG. 5 is a schematic cross-sectional view of the power storage module of the comparative example. FIG. 6 is a schematic plan view of the power storage module according to the modified example.

Hereinafter, one embodiment will be described in detail with reference to the accompanying drawings. In the description of the drawings, the same reference numerals are used for the same or equivalent elements, and duplicate description is omitted. Each figure shows a coordinate system defined by the X-axis, Y-axis, and Z-axis. The X-axis direction (second direction) is a direction that intersects (here, orthogonal) with the Y-axis direction (third direction) and the Z-axis direction (first direction), and the Y-axis direction is the X-axis direction and Z. This is the direction that intersects the axial direction (here, orthogonal). The Z-axis direction is, for example, the vertical direction, and the X-axis direction and the Y-axis direction are, for example, the horizontal direction.

FIG. 1 is a schematic side view showing a power storage device according to an embodiment. The power storage device 1 shown in FIG. 1 can be used as a battery for various vehicles such as forklifts, hybrid vehicles, and electric vehicles. The power storage device 1 includes a laminated body 2, connecting members 3 and 4 electrically connected to the laminated body 2, a pair of restraint members 5 for restraining the laminated body 2, and a pair of restraint members 5 for the laminated body 2. A pair of insulating members 7 arranged between them are provided.

The laminated body 2 has a plurality of power storage modules 11 laminated along the Z-axis direction, and a positive electrode current collector plate 12 and a negative electrode current collector plate 13 provided so as to come into contact with the power storage module 11. .. In the following, the Z-axis direction may be simply referred to as the “stacking direction”. In the example shown in FIG. 1, the laminated body 2 has two power storage modules 11, one positive electrode current collector plate 12, and two negative electrode current collector plates 13. One positive electrode current collector plate 12 is arranged between two power storage modules 11. The two negative electrode current collector plates 13 are arranged at both ends of the laminated body 2 in the Z-axis direction.

The connecting member 3 is a conductive member (bus bar) that functions as a positive electrode of the power storage device 1. The connecting member 3 extends in the stacking direction (Z-axis direction) of the power storage module 11. The connecting member 3 is, for example, a metal plate. The metal plate is, for example, a copper plate, an aluminum plate, a titanium plate, or a nickel plate. The metal plate may be, for example, a stainless steel plate (SUS301, SUS304, etc.) or an alloy plate containing two or more metals selected from the group consisting of copper, aluminum, titanium, and nickel. The connecting member 3 is electrically connected to the positive electrode current collector plate 12 included in the laminated body 2.

The connecting member 4 is a conductive member (bus bar) that functions as a negative electrode of the power storage device 1. The connecting member 4 extends in the stacking direction (Z-axis direction) of the power storage module 11. Like the connecting member 3, the connecting member 4 is, for example, a metal plate. The connecting member 4 may be the same metal plate as the connecting member 3, or may be a different metal plate. The connecting member 4 is electrically connected to the negative electrode current collector plate 13 included in the laminated body 2.

Each of the pair of restraint members 5 is a member that applies a restraining force (load) along the Z-axis direction to the laminated body 2. Each of the pair of restraint members 5 is formed of, for example, a conductive metal material (for example, an alloy such as copper, aluminum, titanium, nickel, or stainless steel). The pair of restraint members 5 may be connected to each other via a connecting member 6 using, for example, a fastening member (for example, a bolt 6A and a nut 6B). In this case, each of the pair of restraint members 5 is provided with a through hole through which the bolt 6A is inserted.

Each of the pair of insulating members 7 is, for example, a sheet-like member having an insulating property, and has a substantially rectangular parallelepiped shape. Each of the pair of insulating members 7 is interposed between the laminated body 2 (negative electrode current collector plate 13) and the restraining member 5. Each of the pair of insulating members 7 is in contact with the negative electrode current collector plate 13. That is, in the present embodiment, the power storage modules 11 are arranged so that the negative electrode termination electrodes 19 (see FIG. 3), which will be described later, are arranged at both ends of the laminated body 2 in the Z-axis direction.

Examples of materials forming each of the pair of insulating members 7 include polypropylene (PP), polyphenylene sulfide (PPS), and nylon 66 (PA66). At least one of the pair of insulating members 7 may have elasticity. The length (thickness) of the insulating member 7 along the Z-axis direction is, for example, 1 mm or more and 10 mm or less.

Next, the details of the power storage module 11 will be described with reference to FIGS. 2 and 3. FIG. 2 is a schematic plan view of the power storage module included in the power storage device of FIG. FIG. 3 is a schematic cross-sectional view taken along the line III-III of FIG. As shown in FIGS. 2 and 3, the power storage module 11 is a cell cell having a substantially rectangular parallelepiped shape. The power storage module 11 is, for example, a secondary battery such as a nickel hydrogen secondary battery and a lithium ion secondary battery. The power storage module 11 may be an electric double layer capacitor. The power storage module 11 may be an all-solid-state battery.

In the present embodiment, the power storage module 11 is a bipolar lithium ion secondary battery. The power storage module 11 is sandwiched between the positive electrode current collector plate 12 and the negative electrode current collector plate 13 in the Z-axis direction, and is electrically connected to the connecting member 3 via the positive electrode current collector plate 12 and also negative electrode current collector. It is electrically connected to the connecting member 4 via the plate 13.

The power storage module 11 includes a laminate 14, a sealing member 15, a plurality of flexible printed circuit boards 50, and a plurality of support members 60. The laminate 14 has a plurality of bipolar electrodes 16, a plurality of separators 17, a positive electrode terminal electrode 18, and a negative electrode terminal electrode 19. The plurality of bipolar electrodes 16 and the plurality of separators 17 are alternately arranged along the Z-axis direction. In the present embodiment, the stacking direction of the bipolar electrodes 16 coincides with the stacking direction of the power storage module 11.

Each of the plurality of bipolar electrodes 16 includes an electrode body 21, a positive electrode layer 22 (active material layer), and a negative electrode layer 23 (active material layer). The electrode body 21 has a pair of main surfaces 21a and 21b that intersect the Z-axis direction. A positive electrode layer 22 is provided on the main surface 21a, and a negative electrode layer 23 is provided on the main surface 21b. That is, the bipolar electrode 16 includes two electrode layers having different polarities formed on both surfaces of the electrode body 21. Therefore, the electrode body 21 is sandwiched between the positive electrode layer 22 and the negative electrode layer 23 along the Z-axis direction. The electrode body 21 may be composed of one electrode plate or two electrode plates. When the electrode body 21 is composed of two electrode plates, the bipolar electrode 16 is an electrode plate having a positive electrode layer 22 formed on one surface and another electrode having a negative electrode layer 23 formed on one surface. The plates may be formed by superimposing the plates so that the surfaces on which the electrode layers are not formed are in contact with each other.

The electrode body 21 is a sheet-shaped conductive member. The electrode body 21 has, for example, a structure in which a plurality of metal foils containing different types of metals are integrated. A plurality of metal foils are joined to each other. Each metal foil is, for example, a copper foil, an aluminum foil, a titanium foil, or a nickel foil. Each metal foil is, for example, a stainless steel foil (for example, SUS304, SUS316, and SUS301 specified in JIS G 4305: 2015), a plated steel plate (for example, JIS G 3141: 2011, etc.). It may be a cold-rolled steel sheet (SPCC, etc.)) or a plated stainless steel sheet, or an alloy foil containing two or more metals selected from the group consisting of copper, aluminum, titanium and nickel. You may. From the viewpoint of ensuring mechanical strength, the electrode body 21 may include an aluminum foil. When the electrode body 21 does not contain the aluminum foil, the surface of the metal foil may be coated with aluminum. The thickness of the electrode body 21 is, for example, 5 μm or more and 70 μm or less.

The electrode body 21 has a main body portion 21c having a rectangular shape in a plan view and a tab 21d integrated with the main body portion 21c. The positive electrode layer 22 and the negative electrode layer 23 are formed on the main body portion 21c and not on the tab 21d. The tab 21d extends from the main body 21c in a direction intersecting the Z-axis direction (in the present embodiment, the X-axis direction). The length along the Z-axis direction of the tab 21d and the direction intersecting the extending direction of the tab 21d (in the present embodiment, the Y-axis direction) is the direction intersecting the Z-axis direction of the main body 21c and the extending direction of the tab 21d (the direction intersecting the extending direction of the tab 21d). In this embodiment, it is shorter than the length along the Y-axis direction). Specifically, the tab 21d protrudes in the X-axis direction from the edge extending in the lateral direction (Y-axis direction) of the main body 21c and penetrates the sealing member 15. The tab 21d is used to transmit the voltage of the electrode body 21 to the flexible printed circuit board 50. In the present embodiment, the plurality of bipolar electrodes 16, the positive electrode terminal electrode 18, and the tab 21d of the electrode body 21 of the negative electrode terminal electrode 19 are provided at positions where they overlap each other when viewed from the Z-axis direction.

The positive electrode layer 22 is a layered member containing a positive electrode active material, a conductive auxiliary agent, and a binder, and has a substantially rectangular shape. In other words, the positive electrode layer 22 is an active material layer of the positive electrode (second polarity). The positive electrode active material of the present embodiment is, for example, a composite oxide, metallic lithium, sulfur and the like. The composition of the composite oxide includes, for example, at least one of iron, manganese, titanium, nickel, cobalt, and aluminum, and lithium. Examples of the composite oxide include olivine-type lithium iron phosphate (LiFePO ₄ ). The binder is a material that holds the active material or the conductive auxiliary agent to the surface of the electrode body 21 and maintains the conductive network in the electrode. Examples of binders include fluororesins such as polyvinylidene fluoride, polytetrafluoroethylene and fluororubber, thermoplastic resins such as polypropylene and polyethylene, imide resins such as polyimide and polyamideimide, and alkoxysilyl group-containing resins. Examples thereof include acrylic resins such as poly (meth) acrylic acid, styrene-butadiene rubber (SBR), carboxymethyl cellulose, sodium alginate, alginates such as ammonium alginate, water-soluble cellulose ester crosslinked products, and starch-acrylic acid graft polymers. .. These binders are used alone or in combination.

Examples of conductive auxiliaries include acetylene black, carbon black, and graphite. The viscosity adjusting solvent is, for example, N-methyl-2-pyrrolidone (NMP) or the like.

The negative electrode layer 23 is a layered member containing a negative electrode active material, a conductive auxiliary agent, and a binder, and has a substantially rectangular shape. In other words, the negative electrode layer 23 is an active material layer of the negative electrode (first polarity). The negative electrode active material of the present embodiment is, for example, carbon such as graphite, artificial graphite, highly oriented graphite, mesocarbon microbeads, hard carbon, soft carbon, a metal compound, an element that can be alloyed with lithium or a compound thereof, and boron. Addition carbon etc. Examples of elements that can be alloyed with lithium include silicon and tin. As the conductive auxiliary agent and the binder, the same material as that of the positive electrode layer 22 may be used.

The plurality of bipolar electrodes 16 are laminated along the Z-axis direction. The two bipolar electrodes 16 adjacent to each other in the Z-axis direction include a negative electrode layer 23 provided on the electrode body 21 of one bipolar electrode 16 and a positive electrode layer 22 provided on the electrode body 21 of the other bipolar electrode 16. They are laminated along the Z-axis direction so as to face each other via the separator 17.

The positive electrode terminal electrode 18 is located at one end of the laminated body 14 in the Z-axis direction. The positive electrode terminal electrode 18 includes an electrode body 21 and a positive electrode layer 22 formed on the main surface 21a of the electrode body 21. In the positive electrode terminal electrode 18, an electrode layer such as a negative electrode layer 23 is not formed on the main surface 21b of the electrode body 21. The positive electrode terminal electrode 18 is laminated on the bipolar electrode 16 so that the main surface 21a and the positive electrode layer 22 face the bipolar electrode 16 via the separator 17.

The negative electrode termination electrode 19 is located at the other end of the laminate 14 in the Z-axis direction. The negative electrode terminal electrode 19 includes an electrode body 21 and a negative electrode layer 23 formed on the main surface 21b of the electrode body 21. In the negative electrode terminal electrode 19, an electrode layer such as a positive electrode layer 22 is not formed on the main surface 21a of the electrode body 21. The negative electrode terminal electrode 19 is laminated on the bipolar electrode 16 so that the main surface 21b and the negative electrode layer 23 face the bipolar electrode 16 via the separator 17.

The separator 17 is a layered member that separates two bipolar electrodes 16 adjacent to each other, between the bipolar electrode 16 and the positive electrode terminal electrode 18, and between the bipolar electrode 16 and the negative electrode terminal electrode 19, and is substantially rectangular. It has a shape. The separator 17 is a member that prevents a short circuit between two bipolar electrodes 16 adjacent to each other, between the bipolar electrode 16 and the positive electrode terminal electrode 18, and between the bipolar electrode 16 and the negative electrode terminal electrode 19. The separator 17 may be composed of the electrolyte contained in the positive electrode layer 22 and the negative electrode layer 23. When the separator 17 is composed of a solid electrolyte, the separator 17 may have a substantially rectangular plate shape. The thickness of the separator 17 is, for example, 1 μm or more and 20 μm or less.

The separator 17 is a porous film made of a polyolefin resin such as polyethylene (PE) and polypropylene (PP). The separator 17 may be a woven fabric or a non-woven fabric made of polypropylene, methyl cellulose or the like. The separator 17 may be reinforced with a vinylidene fluoride resin compound.

The sealing member 15 is a member that holds a plurality of bipolar electrodes 16, a plurality of separators 17, a positive electrode terminal electrode 18, and a negative electrode terminal electrode 19 included in the laminated body 14, and has insulating properties. More specifically, the sealing member 15 holds the bipolar electrode 16, the positive electrode terminal electrode 18, and the electrode body 21 constituting the negative electrode terminal electrode 19. When viewed from the Z-axis direction, the sealing member 15 has an outer frame shape (here, a rectangular frame shape) that follows the outer shape of the main body portion 21c of the electrode body 21, and is an outer edge portion of the main body portion 21c of the electrode body 21. Is interposed between two electrode bodies 21 adjacent to each other in the Z-axis direction. The sealing member 15 is joined (for example, welded) to at least one of the main surface 21a and the main surface 21b of the electrode body 21. The sealing member 15 can also function as a short-circuit prevention member that seals the side surface of the laminated body 14 along the Z-axis direction and prevents short-circuiting between the electrode bodies 21.

Examples of the material forming the sealing member 15 include a heat-resistant resin member and the like. Examples of the heat-resistant resin member include polyimide, polypropylene (PP), polyphenylene sulfide (PPS), modified polyphenylene ether (modified PPE), PA66 and the like.

An electrolytic solution (not shown) is housed in the space S sealed by the sealing member 15. Examples of the electrolytic solution include cyclic carbonates, cyclic esters, chain carbonates, chain esters, and ethers. The supporting salt contained in the electrolytic solution is, for example, a lithium salt. Lithium salts are, for example, LiBF ₄ , LiPF ₆ , LiN (FSO ₂ ) ₂ , LiN (SO ₂ CF ₃ ) ₂ , LiN (SO ₂ C2F ₅ ) ₂ , or a mixture thereof.

The plurality of flexible printed substrates 50 transmit signals relating to the voltages of the electrode body 21 of the plurality of bipolar electrodes 16, the electrode body 21 of the positive electrode termination electrode 18, and the electrode body 21 of the negative electrode termination electrode 19 to a monitoring device (not shown). It is a member of. The flexible printed substrate 50 is formed between the electrode bodies 21 of the two bipolar electrodes 16 adjacent to each other, between the electrode body 21 of the bipolar electrode 16 and the electrode body 21 of the positive electrode termination electrode 18, and the electrode body 21 of the bipolar electrode 16. It is provided between the negative electrode terminal electrode 19 and the electrode body 21. More specifically, one flexible printed circuit board 50 is provided for every two electrode bodies 21. The flexible printed circuit board 50 is inserted into a space defined by two tabs 21d adjacent to each other and a sealing member 15.

The plurality of support members 60 are non-conductive members for supporting the tab 21d. Since the flexible printed circuit 50 is provided for each of the two electrode bodies 21, the support member 60 is not provided with the flexible printed circuit 50 among the electrode bodies 21 of the two bipolar electrodes 16 adjacent to each other in the Z-axis direction. It is provided between the two electrode bodies 21. That is, the flexible printed circuit board 50 and the support member 60 are alternately provided. Similar to the flexible printed circuit board 50, the support member 60 is inserted into a space formed by two tabs 21d adjacent to each other and a sealing member 15. The elastic modulus of the support member 60 is smaller than the elastic modulus of the flexible printed circuit board 50. The elastic modulus of an object is a value obtained by dividing the stress applied to the object by the strain of the object. Specifically, the elastic modulus of the support member 60 in the Z-axis direction is smaller than the elastic modulus of the flexible printed circuit 50 in the Z-axis direction.

A support member 60 is provided between the electrode body 21 of the uppermost bipolar electrode 16 and the electrode body 21 of the second-stage bipolar electrode 16 from the top. Similarly, a support member 60 is provided between the electrode body 21 of the lowermost bipolar electrode 16 and the electrode body 21 of the second-stage bipolar electrode 16 from the bottom. For one bipolar electrode 16, a flexible printed circuit board 50 is provided between the bipolar electrode 16 and one of the bipolar electrodes 16 adjacent to each other in the Z-axis direction, and between the two bipolar electrodes 16 adjacent to each other in the Z-axis direction. A support member 60 is provided on the. Details of the flexible printed circuit board 50 and the support member 60 will be described later.

Next, the configurations of the positive electrode current collector plate 12 and the negative electrode current collector plate 13 will be described in more detail. As shown in FIG. 1, the positive electrode current collector plate 12 is a conductive member that comes into contact with the laminated body 14, and has a plate shape. The positive electrode current collector plate 12 is adjacent to the power storage module 11 in the Z-axis direction. That is, the positive electrode current collector plate 12 is arranged so as to come into contact with the electrode body 21 of the positive electrode terminal electrode 18. The positive electrode current collector plate 12 has a main body portion 12a that comes into contact with the electrode body 21 and a protruding portion 12c that protrudes from a part of the edge 12b of the main body portion 12a in the X-axis direction. The protrusion 12c is connected to the connecting member 3. The main body portion 12a is a portion that overlaps the bipolar electrode 16 and the separator 17 in the Z-axis direction, and has a substantially rectangular shape. The thickness of the positive electrode current collector plate 12 is, for example, 1 mm or more and 5 mm or less.

The negative electrode current collector plate 13 is a conductive member that comes into contact with the laminated body 14, and has a plate shape. The negative electrode current collector plate 13 is adjacent to the power storage module 11 in the Z-axis direction like the positive electrode current collector plate 12. That is, the negative electrode current collector plate 13 is arranged so as to come into contact with the electrode body 21 of the negative electrode terminal electrode 19. The negative electrode current collector plate 13 has a main body portion 13a that comes into contact with the electrode body 21 and a protruding portion 13c that protrudes from a part of the edge 13b of the main body portion 13a in the X-axis direction. The protrusion 13c is connected to the connecting member 4. The main body 13a is a portion that overlaps the bipolar electrode 16 and the separator 17 in the Z-axis direction, and has a substantially rectangular shape. The thickness of the negative electrode current collector plate 13 is, for example, 1 mm or more and 5 mm or less.

The two power storage modules 11 are arranged so that the positive electrode termination electrodes 18 face each other. The positive electrode current collector plate 12 is arranged so as to be in contact with the two positive electrode terminal electrodes 18 facing each other. That is, in the present embodiment, one positive electrode current collector plate 12 functions as a positive electrode current collector plate of the two power storage modules 11.

Next, the configurations of the flexible printed circuit board 50 and the support member 60 will be described in more detail. FIG. 4 is an enlarged view of a part of the cross section shown in FIG. FIG. 4 shows three bipolar electrodes 16 arranged in order in the Z-axis direction, one flexible printed circuit board 50, and one support member 60. For convenience of explanation, the bipolar electrode 16 (first electrode) located at the top of the three bipolar electrodes 16 is referred to as "bipolar electrode 16A", and the bipolar electrode 16 (second electrode) located in the middle is referred to as "bipolar". It may be referred to as "electrode 16B", and the bipolar electrode 16 (third electrode) located at the bottom may be referred to as "bipolar electrode 16C". Similarly, the electrode body 21 (first electrode body) of the bipolar electrode 16A is referred to as "electrode body 21A", the electrode body 21 (second electrode body) of the bipolar electrode 16B is referred to as "electrode body 21B", and the bipolar electrode 16C The electrode body 21 (third electrode body) of the above may be referred to as “electrode body 21C”. The separator 17 (first separator) interposed between the bipolar electrode 16A and the bipolar electrode 16B is referred to as "separator 17A", and the separator 17 (second separator) interposed between the bipolar electrode 16B and the bipolar electrode 16C is referred to as "separator 17A". It may be referred to as "separator 17B".

That is, in the example shown in FIG. 4, the bipolar electrode 16A includes an electrode body 21A, a positive electrode layer 22 provided on the main surface 21a of the electrode body 21A, and a negative electrode layer 23 provided on the main surface 21b of the electrode body 21A. And, including. The bipolar electrode 16B includes an electrode body 21B, a positive electrode layer 22 provided on the main surface 21a of the electrode body 21B, and a negative electrode layer 23 provided on the main surface 21b of the electrode body 21B. The bipolar electrode 16C includes an electrode body 21C, a positive electrode layer 22 provided on the main surface 21a of the electrode body 21C, and a negative electrode layer 23 provided on the main surface 21b of the electrode body 21C. The electrode body 21A has a main body portion 21c (first main body portion) provided with the positive electrode layer 22 and the negative electrode layer 23, and a tab 21d (first tab) extending from the main body portion 21c in the X-axis direction. The electrode body 21B has a main body portion 21c (second main body portion) provided with the positive electrode layer 22 and the negative electrode layer 23, and a tab 21d (second tab) extending from the main body portion 21c in the X-axis direction. The electrode body 21C has a main body portion 21c (third main body portion) provided with the positive electrode layer 22 and the negative negative layer 23, and a tab 21d (third tab) extending from the main body portion 21c in the X-axis direction.

The bipolar electrode 16A and the bipolar electrode 16B are laminated along the Z-axis direction so that the negative electrode layer 23 provided on the electrode body 21A and the positive electrode layer 22 provided on the electrode body 21B face each other via the separator 17A. Has been done. The bipolar electrode 16B and the bipolar electrode 16C are laminated along the Z-axis direction so that the negative electrode layer 23 provided on the electrode body 21B and the positive electrode layer 22 provided on the electrode body 21C face each other via the separator 17B. Has been done.

In the example shown in FIG. 4, the flexible printed circuit board 50 is arranged so as to be sandwiched between the tab 21d of the electrode body 21A and the tab 21d of the electrode body 21B in the Z-axis direction. The tip of the flexible printed circuit board 50 is in contact with the outer surface of the sealing member 15. The flexible printed circuit board 50 is a double-sided flexible printed circuit board, and has a surface 50a that intersects the Z-axis direction and a surface 50b that is opposite to the surface 50a. The flexible printed circuit board 50 includes a base film 51, a conductive pattern 52 (first conductive pattern), a conductive pattern 53 (second conductive pattern), a cover film 54, and a cover film 55.

The base film 51 is a film-like insulating member. The material of the base film 51 is polyimide, polyethylene naphthalate, polyethylene terephthalate, or the like. The conductive patterns 52 and 53 are formed of a conductive metal such as copper. The conductive pattern 52 transmits a signal related to the voltage of the electrode body 21A. The conductive pattern 52 is provided on one surface 51a of the base film 51. The conductive pattern 53 transmits a signal relating to the voltage of the electrode body 21B. The conductive pattern 53 is provided on the other surface 51b of the base film 51. The cover films 54 and 55 are film-shaped insulating members. The materials of the cover films 54 and 55 are polyimide, polyethylene naphthalate, polyethylene terephthalate and the like. The cover film 54 is provided on the conductive pattern 52 formed on the surface 51a and covers the conductive pattern 52. The cover film 55 is provided on the conductive pattern 53 formed on the surface 51b and covers the conductive pattern 53. The surface of the cover film 54 constitutes the surface 50a. The surface of the cover film 55 constitutes the surface 50b.

The flexible printed circuit board 50 has a connecting portion 56 in which the electrode bodies 21A and 21B and the conductive patterns 52 and 53 are electrically connected to each other. In this embodiment, the connection portion 56 is located at one end of the flexible printed circuit board 50. The connecting portion 56 is located in a space defined by the tab 21d of the electrode body 21A, the tab 21d of the electrode body 21B, and the sealing member 15, and the tab 21d of the electrode body 21A and the tab of the electrode body 21B in the Z-axis direction. It is sandwiched between 21d. The connecting portion 56 has a surface 56a (first surface) facing the tab 21d of the electrode body 21A and a surface 56b (second surface) facing the tab 21d of the electrode body 21B. The surface 56a is a surface 50a at the connecting portion 56. The surface 56b is a surface 50b at the connecting portion 56.

The surface 56a is provided with an opening 56c (first opening). The opening 56c is a portion where the cover film 54 is missing, and a part of the conductive pattern 52 (the tip portion in the present embodiment) is exposed from the opening 56c. The opening 56c is provided at a position overlapping the tab 21d of the electrode body 21A when viewed from the Z-axis direction. The conductive pattern 52 is electrically connected to the tab 21d of the electrode body 21A via the opening 56c. In the present embodiment, the conductive adhesive 57 is filled in the opening 56c, and the conductive pattern 52 is connected to the tab 21d of the electrode body 21A by the adhesive 57.

The surface 56b is provided with an opening 56d (second opening). The opening 56d is a portion where the cover film 55 is missing, and a part of the conductive pattern 53 (the tip portion in the present embodiment) is exposed from the opening 56d. The opening 56d is provided at a position overlapping the tab 21d of the electrode body 21B when viewed from the Z-axis direction. The conductive pattern 53 is electrically connected to the tab 21d of the electrode body 21B via the opening 56d. In the present embodiment, the conductive adhesive 58 is filled in the opening 56d, and the conductive pattern 53 is connected to the tab 21d of the electrode body 21B by the adhesive 58.

In the example shown in FIG. 4, the support member 60 is arranged so as to be sandwiched between the tab 21d of the electrode body 21B and the tab 21d of the electrode body 21C in the Z-axis direction. The tip of the support member 60 is in contact with the outer surface of the sealing member 15. The tip of the support member 60 is located in a space defined by the tab 21d of the electrode body 21B, the tab 21d of the electrode body 21C, and the sealing member 15. The support member 60 supports the tab 21d of the electrode body 21B and the tab 21d of the electrode body 21C in the Z-axis direction. The support member 60 has a surface 60a that intersects the Z-axis direction and a surface 60b that is opposite to the surface 60a. The surface 60a faces the tab 21d of the electrode body 21B. The surface 60b faces the tab 21d of the electrode body 21C.

The surface 60a is provided with a recessed portion 60c that is recessed in the Z-axis direction. In the present embodiment, the adhesive 61 is filled in the recessed portion 60c, and the support member 60 is fixed to the tab 21d of the electrode body 21B by the adhesive 61. The surface 60b is provided with a recessed portion 60d that is recessed in the Z-axis direction. In the present embodiment, the adhesive 62 is filled in the recess 60d, and the support member 60 is fixed to the tab 21d of the electrode body 21C by the adhesive 62. As the adhesives 61 and 62, for example, non-conductive adhesives are used.

The base film 51, the conductive patterns 52, 53, and the cover films 54, 55 so that the length (thickness) of the flexible printed circuit 50 in the Z-axis direction is equal to the distance between the two tabs 21d in the Z-axis direction. The length (thickness) of the above in the Z-axis direction is appropriately adjusted. Similarly, the thickness of the support member 60 is adjusted so that the length (thickness) of the support member 60 in the Z-axis direction is equal to the distance between the two tabs 21d in the Z-axis direction.

Next, an example of a step of assembling the flexible printed circuit board 50 and the support member 60 to the laminated body 14 will be described. First, a plurality of flexible printed circuit boards 50 having adhesives 57 and 58 coated on the openings 56c and 56d, and a plurality of support members 60 having adhesives 61 and 62 coated on the recesses 60c and 60d, respectively, are prepared. Will be done. Then, the flexible printed circuit board 50 and the support member 60 are alternately sandwiched between the tabs 21d of the electrode bodies 21 adjacent to each other. Then, when the power storage module 11 is housed in the laser or the high temperature tank, the adhesives 57, 58, 61, 62 are melted and then solidified, so that the flexible printed circuit board 50 and the support member 60 are each two. It is glued to the tab 21d. After that, the power storage module 11 is activated, and the voltage is measured via the flexible printed circuit board 50.

Next, the operation and effect of the power storage module 11 will be described while comparing with the power storage module of the comparative example. FIG. 5 is a schematic cross-sectional view of the power storage module of the comparative example. As shown in FIG. 5, the power storage module 111 of the comparative example includes a plurality of flexible printed circuit boards 150 and a plurality of support members 160 in place of the plurality of flexible printed circuit boards 50 and the plurality of support members 60. Mainly different from 11.

The flexible printed circuit board 150 is mainly different from the flexible printed circuit board 50 in that the conductive pattern 53 and the cover film 55 are not provided and that the flexible printed circuit board 150 is provided for each electrode body 21. The flexible printed circuit board 150 is a single-sided flexible printed circuit board. The flexible printed circuit board 150 is arranged between the tabs 21d of the two electrode bodies 21 adjacent to each other in the Z-axis direction. Further, the flexible printed circuit board 150 is also arranged under the electrode body 21 of the positive electrode terminal electrode 18. An opening 56c is provided on the surface 150a of the flexible printed circuit 150 so that a part of the conductive pattern 52 is exposed, and the conductive pattern 52 is electrically connected to the tab 21d of the electrode body 21 via an adhesive 57. It is connected. No opening is provided on the surface 150b of the flexible printed circuit board 150.

The support member 160 is mainly different from the support member 60 in that it is provided between the flexible printed circuit board 150 and the tab 21d. Since the distance in the Z-axis direction of the tabs 21d of the two electrode bodies 21 adjacent to each other in the Z-axis direction is longer than the length (thickness) in the Z-axis direction of the flexible printed circuit 150, the support member is used to fill the difference. 160 is provided. The surface 160a of the support member 160 is provided with a recessed portion 160c that is recessed in the Z-axis direction. The adhesive 61 is filled in the recess 160c, and the support member 160 is fixed to the surface 150b of the flexible printed circuit board 150 by the adhesive 61. The surface 160b of the support member 160 is provided with a recessed portion 160d that is recessed in the Z-axis direction. The adhesive 62 is filled in the recess 160d, and the support member 160 is fixed to the tab 21d of the electrode body 21 by the adhesive 62.

In the power storage module 111, a flexible printed circuit board 150 is provided for each electrode body 21. Therefore, in the manufacturing process of the power storage module 111, the number of man-hours for assembling the flexible printed circuit 150 to connect to the electrode body 21 and the monitoring device increases, and the manufacturing efficiency of the power storage module 111 may decrease.

On the other hand, in the power storage module 11, the connection portion 56 of the flexible printed circuit board 50 is sandwiched between the tab 21d of the electrode body 21A of the bipolar electrode 16A and the tab 21d of the electrode body 21B of the bipolar electrode 16B. The conductive pattern 52 is electrically connected to the tab 21d of the electrode body 21A via the opening 56c provided on the surface 56a of the connecting portion 56, and is conductive through the opening 56d provided on the surface 56b of the connecting portion 56. The pattern 53 is electrically connected to the tab 21d of the electrode body 21B. That is, one flexible printed circuit board 50 is provided for the two electrode bodies 21A and 21B. Therefore, as compared with the case where one flexible printed circuit board 150 is provided for each electrode body 21 as in the comparative example, the assembling man-hours for connecting the flexible printed circuit board 50 to the electrode body 21 and the monitoring device is increased. Can be reduced. As a result, it becomes possible to improve the manufacturing efficiency of the power storage module 11. Moreover, since the number of the flexible printed circuit board 50 and the support member 60 can be reduced, the cost can be reduced.

Since the support member 60 is arranged so as to be sandwiched between the tab 21d of the electrode body 21B and the tab 21d of the electrode body 21C in the Z-axis direction, the 21d of the electrode bodies 21B and 21C are supported by the support member 60. Therefore, even if a force is applied to the 21d of the electrode bodies 21B and 21C from the flexible printed circuit board 50, the bending of the 21d of the electrode bodies 21B and 21C is suppressed, so that the 21d of the electrode bodies 21B and 21C may break. It can be reduced.

For example, due to the dimensional tolerance of the flexible printed circuit 50 or the like, the length of the connecting portion 56 in the Z-axis direction is larger than the distance between the tab 21d of the electrode body 21A and the tab 21d of the electrode body 21B in the Z-axis direction. May become. Since the elastic modulus of the support member 60 is smaller than the elastic modulus of the flexible printed circuit board 50, the support member 60 is compressed in the Z-axis direction to absorb the dimensional tolerance of the flexible printed circuit board 50 and the like.

Due to the expansion of the power storage module 11 due to the use of the power storage device 1, a force may be applied to the electrode bodies 21B and 21C along the Z-axis direction. If the support member 60 is not elastically deformed, the tabs 21d of the electrode bodies 21B and 21C may bend, and the tabs 21d of the electrode bodies 21B and 21C may break. However, since the elastic modulus of the support member 60 is smaller than the elastic modulus of the flexible printed circuit 50, the support member 60 is compressed in the Z-axis direction, so that the bending of the tabs 21d of the electrode bodies 21B and 21C is suppressed. It is possible to reduce the possibility that the tabs 21d of the electrode bodies 21B and 21C will break.

Although one embodiment of the present disclosure has been described in detail above, the present disclosure is not limited to the above embodiment.

For example, the plurality of flexible printed circuit boards 50 may be integrated at an end opposite to the connecting portion 56. Similarly, the flexible printed circuit board 50 and the support member 60 may be integrated at an end opposite to the connecting portion 56.

A non-conductive resin material may be arranged or filled between the flexible printed circuit board 50 and the support member 60 at the end portion on the connection portion 56 side. Specifically, the resin material is arranged or filled so as to cover the surfaces in the X-axis direction and the Y-axis direction that are not covered by the flexible printed circuit board 50 and the support member 60 of the tab 21d. In this case, since the tab 21d is surrounded by the flexible printed circuit board 50, the support member 60, and the resin material, it is possible to prevent the adjacent tabs 21d from being short-circuited by the liquid.

The support member 60 may not be provided at a portion that does not overlap with the tab 21d, and the length of the support member 60 in the X-axis direction may be changed as necessary. The support member 60 may not be provided.

The tab 21d may be formed of a member different from the main body 21c. The tab 21d may have the entire edge extending in the lateral direction of the main body 21c extending in the X-axis direction and penetrating the sealing member 15. The tab 21d may extend in the Y-axis direction from an edge extending in the longitudinal direction of the main body 21c.

In the above embodiment, the plurality of bipolar electrodes 16, the positive electrode termination electrode 18, and the tab 21d of the electrode body 21 of the negative electrode termination electrode 19 are provided at positions overlapping each other when viewed from the Z-axis direction, but are adjacent to each other. The tabs 21d of the two electrode bodies 21 may be provided at positions (different positions) that do not overlap each other when viewed from the Z-axis direction. For example, as shown in FIG. 6, tabs 21d may be alternately provided at two positions different from each other in the Y-axis direction. That is, the tab 21d of the odd-numbered electrode body 21 from the top may be provided at one position, and the tab 21d of the even-numbered electrode body 21 from the top may be provided at the other position.

In this case, the tab 21d of the electrode body 21B is provided at a position different from the tab 21d of the electrode body 21A in the Y-axis direction. The connection portion 56 of the flexible printed circuit board 50 extends in the Y-axis direction so as to overlap both the tab 21d of the electrode body 21A and the tab 21d of the electrode body 21B when viewed from the Z-axis direction. In this configuration, the tab 21d of the electrode body 21B is located between the tab 21d of the electrode body 21A and the tab 21d of the electrode body 21B as compared with the case where the tab 21d of the electrode body 21B is provided at the same position as the tab 21d of the electrode body 21A in the Y-axis direction. The distance is long. Therefore, since the insulation distance between the tab 21d of the electrode body 21A and the tab 21d of the electrode body 21B can be secured, the possibility that the electrode body 21A and the electrode body 21B are short-circuited can be reduced.

Similarly, the tab 21d of the electrode body 21C is provided at a position different from the tab 21d of the electrode body 21B in the Y-axis direction. The support member 60 extends in the Y-axis direction so as to overlap both the tab 21d of the electrode body 21B and the tab 21d of the electrode body 21C when viewed from the Z-axis direction. In this configuration, the tab 21d of the electrode body 21C is located between the tab 21d of the electrode body 21B and the tab 21d of the electrode body 21C as compared with the case where the tab 21d of the electrode body 21C is provided at the same position as the tab 21d of the electrode body 21B in the Y-axis direction. The distance is long. Therefore, since the insulation distance between the tab 21d of the electrode body 21B and the tab 21d of the electrode body 21C can be secured, the possibility that the electrode body 21B and the electrode body 21C are short-circuited can be reduced.

Further, the tabs 21d of the plurality of electrode bodies 21 may be dispersedly arranged at three or more different positions in the Y-axis direction.

11 ... Storage module, 16A ... Bipolar electrode (first electrode), 16B ... Bipolar electrode (second electrode), 16C ... Bipolar electrode (third electrode), 17A ... Separator (first separator), 17B ... Separator (second electrode) Separator), 21A ... Electrode body (first electrode body), 21B ... Electrode body (second electrode body), 21C ... Electrode body (third electrode body), 21d ... Tab (first tab, second tab, third Tab), 22 ... Positive electrode layer (active material layer), 23 ... Negative electrode layer (active material layer), 50 ... Flexible printed substrate, 52 ... Conductive pattern (first conductive pattern), 53 ... Conductive pattern (second conductive pattern) , 56 ... Connection part, 56a ... Surface (first surface), 56b ... Surface (second surface), 56c ... Opening (first opening), 56d ... Opening (second opening), 60 ... Support member ..

Claims (5)

A first electrode body and a first electrode provided on both sides of the first electrode body and containing two active material layers having different polarities from each other.
A second electrode body and a second electrode provided on both sides of the second electrode body and containing two active material layers having different polarities from each other.
A flexible printed circuit including a first conductive pattern that transmits a signal related to the voltage of the first electrode body and a second conductive pattern that transmits a signal related to the voltage of the second electrode body.
With
The first electrode and the second electrode are such that the first polar active material layer provided on the first electrode body and the second polar active material layer provided on the second electrode body face each other. Laminated along the first direction,
The first electrode body includes a first main body portion provided with the two active material layers of the first electrode, and a first tab extending from the first main body portion in a second direction intersecting the first direction. Have,
The second electrode body has a second main body portion provided with the two active material layers of the second electrode, and a second tab extending from the second main body portion in the second direction.
The flexible printed circuit board has a connection portion sandwiched between the first tab and the second tab in the first direction.
The connecting portion has a first surface facing the first tab and a second surface facing the second tab.
A first opening is provided on the first surface at a position overlapping the first tab when viewed from the first direction so that a part of the first conductive pattern is exposed.
A second opening is provided on the second surface at a position overlapping the second tab when viewed from the first direction so that a part of the second conductive pattern is exposed.
The first conductive pattern is electrically connected to the first tab through the first opening.
The second conductive pattern is a power storage module that is electrically connected to the second tab via the second opening. The power storage module according to claim 1, wherein the second tab is provided at a position different from that of the first tab in the first direction and a third direction intersecting the second direction. A third electrode body and a third electrode provided on both sides of the third electrode body and containing two active material layers having different polarities from each other.
A support member for supporting the second tab and
With more
In the second electrode and the third electrode, the first polar active material layer provided on the second electrode body and the second polar active material layer provided on the third electrode body are mutually exclusive. Laminated along the first direction so as to face each other
The third electrode body has a third main body portion provided with the two active material layers of the third electrode, and a third tab extending from the third main body portion in the second direction.
The power storage module according to claim 1 or 2, wherein the support member is arranged so as to be sandwiched between the second tab and the third tab in the first direction. The power storage module according to claim 3, wherein the elastic modulus of the support member is smaller than the elastic modulus of the flexible printed circuit board. The third tab is provided at a position different from that of the second tab in the first direction and the third direction intersecting the second direction.
The power storage module according to claim 3 or 4, wherein the support member is provided so as to overlap the second tab and the third tab when viewed from the first direction.

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